Techniques for dicing substrates during integrated circuit fabrication

ABSTRACT

The invention relates, in one embodiment, to an arrangement configured to support a substrate during a dicing process. The substrate has thereon a first substrate side and a second substrate side. The first substrate side is smoother than the second substrate side. The arrangement includes a nest having a first nest side and a second nest side. The nest includes a grid which defines at least one nest opening. The nest opening has an opening area that is smaller than an area of a die diced from the substrate. The arrangement further includes a vacuum retainer plate having thereon at least one vacuum pedestal. The vacuum pedestal has an upper surface formed of a resilient material. The vacuum pedestal is configured to be disposed through the nest opening when the nest is mated with the vacuum retainer plate. The vacuum pedestal protrudes above the first nest side of the nest when the vacuum pedestal is disposed through the nest opening from the second nest side to support the substrate on the upper surface and lift the substrate off the first nest side when the substrate is positioned on the nest with the first substrate side facing the first nest side and when the nest is mated with the vacuum retainer plate.

CROSS REFERENCE TO RELATED APPLICATION

This is a Divisional application of prior application Ser. No. 09/288,252 filed on Apr. 8, 1999, now U.S. Pat. No. 6,325,059, the disclosure of which is incorporated herein by reference.

The present invention claims priority of co-pending U.S. patent application Ser. No. 09/156,593, filed Sep. 18, 1998, entitled “TECHNIQUES FOR MAINTAINING ALIGNMENT OF CUT DIES DURING SUBSTRATE DICING,” which is incorporated herein by reference in its entirety for all purposes.

BACKGROUND OF THE INVENTION

1. Field of Invention

The present invention relates generally to the fabrication of integrated circuits chips. More particularly, the present invention relates to a nesting apparatus that is suitable for supporting a substrate during a dicing process.

2. Background

During the fabrication of integrated circuit chips, multiple integrated circuit chips are often arranged on a single substrate, e.g., wafer or circuit board, which is eventually diced to separate the integrated circuit chips. Although a substrate may be sawed, or diced, to create individual chips at substantially any point during an overall fabrication process, the substrate is typically sawed after ball grid arrays and dies are formed on the substrate.

FIG. 1a is a diagrammatic representation of a contact, or ball grid array (BGA) side of a conventional substrate. A substrate 102 includes individual integrated circuit chips 112, each of which includes a ball grid array 110 of contacts, as will be appreciated by those skilled in the art. In general, the number of integrated circuit chips 112 formed on substrate 102 may vary, depending upon the size of substrate 102 and the size of each integrated circuit chip 112. Further, the number of balls in each ball grid array 110 may also vary. By way of example, as shown, substrate 102 includes one hundred and forty integrated circuit chips 112, each of which have a ball grid array with sixteen balls.

Substrate 102 also generally includes locator holes 106 which are used for various fabrication processes including, but not limited to, processes used to apply ball grid arrays 110 on chips 112 and processes used to encapsulate substrate 102. “Pick-up points” 116, which are also included on substrate 102, are arranged to enable cameras to check the overall alignment of substrate 102, as necessary, during fabrication.

A representation of the non-BGA side of substrate 102 is shown in FIG. 1b. Non-BGA side of substrate 102 may be considered to be the “die-side” of substrate 102, as non-BGA side typically includes integrated circuit dies 140. As will be appreciated by those skilled in the art, when substrate 102 is diced to form individual integrated circuit chips 112, one side of each integrated circuit chip 112 will have ball grid array 110, while the other side will have integrated circuit due 140.

As mentioned above, in order to separate integrated circuit chips from a substrate, the substrate must be diced with a dicing saw or similar device. Typically, a dicing process involves manually placing the substrate, non-BGA side down, on an adhesive surface, e.g., tape. The tape is arranged to hold the individual integrated circuit chips in place, both during and after dicing. Specifically, the tape is used to prevent the individual integrated circuit chips from rotation and translation with respect to one another.

A substrate is cut from the BGA side, i.e., a substrate is cut with the non-BGA side down, since it is difficult for tape to effectively grip and hold the balls in ball grid arrays, either from the bottom surfaces of the balls or from the side surfaces of the balls. In other words, while tape is capable of securely holding a substantially smooth surface such as the dies on a substrate during dicing, the tape is not as effective in securely holding an uneven surface, such as the overall surface of ball grid arrays, during dicing.

Once a substrate is placed on tape with the BGA side up, the tape and the substrate are manually loaded on a vacuum chuck for dicing. In other words, the tape and the substrate are aligned on a vacuum chuck, tape-side down, such that the vacuum from the vacuum chuck effectively “grips” the tape and the board. While the tape and the substrate are held on the vacuum chuck, a dicing saw is used to automatically dice the integrated circuit chips. As will be appreciated by those skilled in the art, the dicing saw dices the substrate to form the integrated circuit chips, substantially without cutting through the tape.

Once the integrated circuit chips are separated, the chips must be removed from the tape. A vacuum is generally not used to remove the chips from the tape, since the chips are often not accurately aligned on the tape. Typically, a person may remove each chip, BGA side up, from the tape, then place each chip, BGA side down, in a holding tray which may be used to transport the chips to a subsequent fabrication process. The use of manual processes, however, is often time-consuming and inaccurate.

Alternatively, in lieu of a manual process, a pick-and-place machine may be used to remove the chips from the tape, and place the chips in holding trays. As was the case with manually removing chips from the tape, the use of pick-and-place machines is often time consuming. By way of example, a pick-and-place machine must line up each chip prior to picking that chip off the tape. In addition, pick-and-place machines are additional pieces of fabrication equipment that are generally separate from dicing machines. Therefore, an overall dicing process is likely to require an additional manual process of transporting the tape and the diced chips to the pick-and-place machine.

The use of tape in dicing processes is often undesirable as the tape may be relatively expensive, and must be disposed of once the dicing process is completed. In addition, adhesives on the tape may remain on a chip after the dicing process, thereby creating residue that may be difficult to remove. When residue is not properly removed from a chip, subsequent fabrication steps, as well as the integrity of the chip, may be compromised. The use of tape also generally requires manual handling, e.g., placing a substrate on tape. As will be appreciated by those skilled in the art, in addition to being both tedious and time consuming, manual processes often increase the likelihood that a substrate may be mishandled or become contaminated.

Hence, what is desired is a method and an apparatus for efficiently and substantially automatically dicing a substrate to form individual integrated circuit chips. In other words, what is desired is a method and an apparatus for securely holding a substrate, without the use of tape, during a dicing process.

SUMMARY OF THE INVENTION

The invention relates, in one embodiment, to an arrangement configured to support a substrate during a dicing process. The substrate has thereon a first substrate side and a second substrate side. The first substrate side is smoother than the second substrate side. The arrangement includes a nest having a first nest side and a second nest side. The nest includes a grid which defines at least one nest opening. The nest opening has an opening area that is smaller than an area of a die diced from the substrate. The arrangement further includes a vacuum retainer plate having thereon at least one vacuum pedestal. The vacuum pedestal has an upper surface formed of a resilient material. The vacuum pedestal is configured to be disposed through the nest opening when the nest is mated with the vacuum retainer plate. The vacuum pedestal protrudes above the first nest side of the nest when the vacuum pedestal is disposed through the nest opening from the second nest side to support the substrate on the upper surface and lift the substrate off the first nest side when the substrate is positioned on the nest with the first substrate side facing the first nest side and when the nest is mated with the vacuum retainer plate.

In another embodiment, the invention relates to an arrangement configured to support a substrate during a dicing process. The substrate has a first substrate side and a second substrate side. The first substrate side is smoother than the second substrate side. The arrangement includes a nest having a first nest side and a second nest side. The nest includes a grid which defines at least one nest opening. The nest opening has an opening area that is smaller than an area of a die diced from the substrate. The arrangement also includes a vacuum retainer plate having thereon at least one vacuum pedestal. There is further included a resilient capping arrangement configured to be disposed atop the vacuum pedestal. The vacuum pedestal includes the resilient cap arrangement, which is configured to be disposed through the nest opening when the nest is mated with the vacuum retainer plate. The resilient capping arrangement protrudes above the first nest side of the nest when the vacuum pedestal is disposed through the nest opening from the second nest side to lift the substrate off the first nest side when the substrate is positioned on the nest with the first substrate side facing the first nest side and when the nest is mated with the vacuum retainer plate.

These and other advantages of the present invention will become apparent upon reading the following detailed description, and studying the various figures of the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may best be understood by reference to the following description taken in conjunction with the accompanying drawings in which:

FIG. 1a is a diagrammatic representation of a ball grid array side of a conventional substrate.

FIG. 1b is a diagrammatic representation of a die side of the conventional substrate of FIG. 1a.

FIG. 2a is a diagrammatic top-view representation of a nest in accordance with a first embodiment of the present invention.

FIG. 2b is a diagrammatic perspective representation of the nest of FIG. 2a in accordance with an embodiment of the present invention.

FIG. 3 is a process flow diagram which illustrates the steps associated with forming individual chips from a substrate in accordance with an embodiment of the present invention.

FIG. 4a is a diagrammatic top-view representation of a nest in accordance with a second embodiment of the present invention.

FIG. 4b is a diagrammatic top-view representation of a nest in accordance with a third embodiment of the present invention.

FIG. 5a is a diagrammatic perspective representation of a nest in accordance with a fourth embodiment of the present invention.

FIG. 5b is a diagrammatic perspective representation of a vacuum retainer plate including a vacuum block platform and a base plate in accordance with an embodiment of the present invention.

FIG. 5c is a diagrammatic close-up representation of retainer walls substantially surrounding a nest opening in accordance with an embodiment of the present invention.

FIG. 6 is a process flow diagram which illustrates the steps associated with forming individual chips from a substrate in accordance with an embodiment of the present invention.

FIGS. 7A and 7B depict, in accordance with one embodiment of the present invention, a vacuum block platform, which includes a vacuum pedestal base and a vacuum pedestal portion.

FIG. 8 illustrates, in accordance with one embodiment of the present invention, an exemplary clamp for attaching a vacuum pedestal portion to a vacuum pedestal base.

FIG. 9 illustrates, in accordance with one embodiment of the present invention, a top view of a representative vacuum pedestal.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The present invention will now be described in detail with reference to a few preferred embodiments thereof as illustrated in the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be obvious, however, to one skilled in the art, that the present invention may be practiced without some or all of these specific details. In other instances, well known structures and process steps have not been described in detail in order not to unnecessarily obscure the present invention.

In accordance with one embodiment of the present invention, a nest apparatus is arranged, in conjunction with a vacuum, to securely hold a substrate during a dicing process without the use of tape. A substrate is placed, ball grid array (BGA) side down, into a nest which is then mounted on a vacuum chuck for dicing. During dicing, the nest and the vacuum effectively constrain the substrate and, subsequently, the individual chips formed by dicing the substrate, from translational and rotational movement. When the nest and the diced chips are removed from the vacuum chuck after dicing, the diced chips are essentially ready to be removed from the nest, as for example using a pick and place machine.

In accordance with one embodiment of the present invention, a nest apparatus is arranged, in conjunction with a vacuum retainer plate arrangement, to securely hold a substrate during the dicing process without the use of tape. The substrate is placed, ball grip array (BGA) side up, into a nest which is then mounted on the vacuum retainer plate for dicing. By mounting the nest on the vacuum retainer plate, vacuum pedestals on the vacuum retainer plate protrude through the nest openings to raise the substrate above the upper surface of the nest. The top surface of the vacuum pedestal also forms a vacuum seal with the smooth undersurface of the die to be cut, allowing the die to be held securely to the top surface of the vacuum pedestal when the vacuum is turned on. Because the substrate is raised slightly above the top surface of the nest, the die saw may protrude below the thickness of the substrate without risking damage to either the nest or the saw blade. During cutting, the saw is disposed within channels which are present between vacuum pedestals in the vacuum retainer plate. The recessed channels may be sized to permit some degree of fluctuation in side to side placement of the saw. Increasing the width of the channels will decrease the top surface area of each vacuum pedestal, but that will not significantly impact the ability of the vacuum to hold the cut die on top of the vacuum pedestal.

After the substrate is cut, a top cover is then placed over the nest containing the cut dies of the substrate. The top cover preferably has contact posts which hold down each individual die. This combination of the top cover, the nest and the cut dies in between forms a covered nest fixture, which is then lifted off the vacuum block platform. By lifting the covered nest fixture from the vacuum block platform, the individual dies are permitted to drop back down to the nest surface. More specifically, each nest opening has retainer walls disposed adjacent to its opening. When each cut die drops down to rest on the top surface of the nest, the retainer walls securely hold each cut die by their edges, thereby preventing the translational and rotational motion of the cut die. The cut dies, being held substantially immobile by the retainer walls, as well as trapped between the contact posts of the top cover and the nest, may now be further processed (e.g., washing, rinsing, drying) while being kept substantially immobile. Since each cut die is held substantially immobile on the surface of the nest by the retainer walls, the diced chips are essentially aligned and ready to be removed from the nest when the top plate is removed, as for example, using a pick and place machine. In this manner, the overall dicing process is automated and the cut dies are held immobile during cutting, transporting, and subsequent processing without the use of tape as well as aligned for subsequent picking and placing.

The use of a nest to hold a substrate during dicing, without tape, eliminates problems associated with adhesive residue left on chips by the tape, as well as issues associated with disposing of the tape. Using a nest also allows the overall dicing process to be more automated, as the need for manual processes including mounting a substrate on a vacuum chuck and removing chips from the tape may be eliminated.

Referring to FIGS. 2a and 2 b, one embodiment of a nest mechanism will be described in accordance with the present invention. FIG. 2a is a diagrammatic top-view representation of a nest mechanism, while FIG. 2b is a substantially perspective representation of the nest mechanism. It should be appreciated that for ease of illustration, FIGS. 2a and 2 b are not drawn to scale. A nest 202 is configured, or otherwise arranged, to translationally and rotationally reduce the movement of a substrate positioned within nest 202. While nest 202 may be made of a variety of different materials, in one embodiment, nest 202 is fabricated from stainless steel, due to the fact that stainless steel is both lightweight and strong. By way of example, nest 202 may be fabricated from 440C stainless. Alignment pins 210 on nest 202 are used to engage locator holes on a substrate in order to position the substrate with respect to nest 202. In general, substantially any suitable mechanism may be used to align a substrate within nest 202.

When a substrate is properly positioned with respect to nest 202, the substrate rests against a grid arrangement 212. Although the die side of a substrate may be placed “face down” on nest 202, in the described embodiment, the BGA side of the substrate is placed onto nest 202. Grid arrangement 212 defines openings 214 which accommodate the ball grid arrays of a substrate. That is, the ball grid arrays of the substrate are at least partially placed within openings 214. As shown, while grid arrangement 212 defines one hundred and forty openings 214, the number of openings 214 may typically be widely varied.

Each opening 214 effectively “holds” one ball grid array such that at least one of the balls, or contacts, of the ball grid array lightly contacts the walls of grid arrangement 212. In one embodiment, the sides of four “corner” balls of a ball grid array may contact the corners of grid arrangement 212 in each opening 214. As such, while openings 214 may be substantially rectangularly shaped, the corners of openings 214 may be slightly curved to facilitate contact of only the sides of corner balls against grid arrangement 212. It should be appreciated, however, that in some embodiments, substantially all balls along the sides of each ball grid array may contact the walls of grid arrangement 212.

Nest 202 may be mounted against a vacuum chuck that is a part of a dicing saw assembly. The vacuum chuck typically generates a vacuum which engages the substrate mounted on nest 202 through openings 214. Generally any suitable mechanism may be used to mount nest 202 against a vacuum chuck, including, but not limited to, pilot locator holes 218 which are arranged to fit over dowels, or similar structures, on the vacuum chuck.

As will be described below with respect to FIG. 3, when nest 202 and, hence, a substrate, are mounted on a vacuum chuck, a dicing saw may then cut the substrate to generate separate integrated circuit chips from the substrate. Nest 202 is effective to hold the separate integrated circuit chips substantially in place by locating the balls of the ball grid array of each chip. The vacuum from the vacuum chuck holds each chip against grid arrangement 212, while the contact between the sides of at least one of the balls of the chip and the walls of grid arrangement prevents the chip from rotating and translating. By preventing chips from rotating and translating, subsequent pick and place processes used to remove chips from nest 202 may be efficiently accomplished. Further, preventing chips from freely moving during and after dicing also reduces the likelihood that the dicing process may inaccurately cut the chips from the substrate.

In the embodiment as shown, a stepped section 216, or channeled section, is arranged to receive the cut sides of the substrate after the substrate has been cut, or diced. In other words, scrap material from the substrate falls into stepped section 216, and, as a result, is effectively prevented from migrating with respect to nest 202, and potentially negatively affecting dicing processes. Vacuum openings 222 may be used, in addition to stepped section 216, in order to further prevent scrap material from migrating during and after a dicing process. Specifically, vacuum generated by a vacuum chuck may engage the scrap material through vacuum openings 222, thereby essentially forcing the scrap material to remain within stepped section 216.

With reference to FIG. 3, one method of implementing the nest of FIGS. 2a and 2 b in the creation of individual chips from a substrate will be described. FIG. 3 is a process flow diagram which illustrates the steps associated with forming individual chips from a substrate in accordance with an embodiment of the present invention. The process 302 begins in step 304 in which a substrate to be diced is loaded into a nest. In general, loading a substrate into a nest includes aligning the substrate with respect to the nest to properly position the substrate. In one embodiment, as described above, aligning the substrate with respect to the nest includes positioning the substrate such that alignment pins on the nest interface with locator holes on the substrate. When the substrate is properly aligned, the balls in each ball grid array located on the BGA side of the substrate are effectively positioned in the nest openings of the nest.

After the substrate is loaded into the nest in step 304, the nest is loaded onto a vacuum chuck in step 306. Specifically, the nest is automatically loaded onto the vacuum chuck such that the BGA side of the substrate is in communication with the vacuum provided by the vacuum chuck. In other words, the nest is positioned to enable the suction from the vacuum to effectively engage the BGA side of the substrate. As will be appreciated by those skilled in the art, the vacuum chuck may be a part of an overall dicing saw assembly that is arranged to dice the substrate into individual chips.

When the nest is loaded onto the vacuum chuck, then in step 308, a dicing process is performed on the substrate. In other words, the dicing saw, e.g., a diamond wheel, of the dicing saw assembly is used to cut the substrate to form individual chips. After the dicing process is completed, process flow moves to step 310 in which a cover is placed over the nest. The cover is arranged to prevent the individual chips from moving once the nest is removed from the vacuum chuck. While the configuration of the cover may vary widely, in one embodiment, the cover is arranged with protrusions which lightly press against the non-BGA side of the individual chips to hold portions of the BGA side of the individual chips against the nest. It should be appreciated, however, that the cover is generally not arranged to hold scrap material, e.g., extra material which is left at the sides of the substrate after individual chips are formed. Rather, the cover may be arranged to allow the scrap material to be washed out of the nest, as will be described below.

The covered nest fixture is removed from the vacuum chuck in step 312, and moved to a “wash and dry” unit. In one embodiment, the covered nest fixture is automatically removed from the vacuum chuck, and moved to the wash and dry unit. A wash and dry unit may be a part of the overall dicing saw apparatus, and is generally arranged to remove residue left during the dicing process from the individual chips. The wash and dry unit is further arranged to dry the chips once they have been cleaned. In general, a wash and dry unit is arranged to remove dirt, debris, and dust that has accumulated during the dicing process.

In step 314, the diced substrate is washed and dried in the covered nest fixture. During a washing process, the BGA side of the chips is effectively either sprayed with fluid, e.g., water, through the nest openings in the nest, or submerged in fluid. In addition to washing the chips, the spraying of fluid, as well as the submerging of the nest in fluid, is also effective to remove the scrap material from the nest. In other words, the scrap material is allowed to “float” out of the nest during washing, as the scrap is not held within the covered nest fixture. The wash and dry unit may be arranged to capture scrap material and residue such that the scrap material and residue may be readily removed from the wash and dry unit.

After the chips are washed and dried, the covered nest fixture is offloaded from the wash and dry unit in step 316. In one embodiment, the covered nest fixture is automatically offloaded onto a staging block. Once the covered nest fixture is offloaded, then in step 318, the cover is removed, thereby exposing the diced substrate, or individual chips. Finally, in step 320, the chips are removed from the nest. Typically, the chips are removed from the nest such that they may be placed in trays for further processing. While substantially any suitable method may be used to remove the chips, methods include using a pick and place machine to remove the chips from the nest. In the described embodiment, the pick and place machine is a part of the overall dicing saw assembly. That is, a single apparatus may be used to both dice the substrate into individual integrated circuit chips and to remove the diced chips from the nest. However, it should be appreciated that the pick and place machine may, alternatively, be separate from the dicing saw assembly. When the chips are removed from the nest, the process of forming individual chips is completed.

As shown in FIG. 2a, a nest may be rectangularly shaped such that the nest is arranged to accommodate substantially rectangularly shaped substrates. In general, however, it should be appreciated that the configuration of a nest may vary widely. For example, the overall size and shape of a nest may change, depending upon the size and the shape of the substrates that the nest is intended to support. Further, the size and the shape of openings in a nest, i.e., nest openings, through which the balls on a substrate may at least partially protrude, as described above with respect to FIG. 2a, may vary depending upon the number of and orientation of balls on the substrate or, more specifically, each chip on the substrate. As such, the grids of the nest support the substrate, which are arranged to provide minimal contact on the balls as necessary to support the substrate during a dicing process, may take on different orientations.

FIG. 4a is a diagrammatic top-view representation of a nest in accordance with a second embodiment of the present invention. Like nest 202 of FIGS. 2a and 2 b, a nest 402 includes pilot locator holes 406, which may be used to hold nest 402 against a vacuum chuck. Nest 402 also includes alignment pins 410 which, as described above, are arranged to align a substrate with respect to nest 402. A grid 414 defines nest openings 418 which, in the described embodiment, are substantially circular in shape. Circularly shaped nest openings 418 may accommodate ball grid arrays which have a circular footprint. In other words, each circularly shaped nest opening 418 may be arranged to accommodate a ball grid array in which the balls are arranged in a substantially circular pattern. Alternatively, each circularly shaped nest opening 418 may be arranged to accommodate a ball grid array with a polygonal, e.g., rectangular, footprint.

FIG. 4b is a diagrammatic top-view representation of a nest in accordance with a third embodiment of the present invention. A nest 432 includes a grid 434 that effectively defines nest openings 438. As shown, nest openings 438 are polygonal in shape. Specifically, in the described embodiment, nest openings 438 are hexagonal in shape. However, it should be appreciated that nest openings 438 may generally take any suitable polygonal shape.

Nest openings 438 are arranged such that they may accommodate ball grid arrays which have a footprint which is of substantially the same shape as nest openings 438. It should be appreciated, however, that nest openings 438 may be suitable for accommodating ball grid arrays which have a different footprint than that of nest openings 438. For example, hexagonally shaped nest openings 438 may accommodate ball grid arrays which are arranged in a substantially rectangular orientation. Alternatively, hexagonally shaped nest openings 438 may also accommodate ball grid arrays which are shaped in a substantially triangular orientation.

FIGS. 5a and 5 b illustrate in accordance with one embodiment of the present invention, a combination vacuum retainer plate/nest mechanism which permits dicing to be performed with the BGA side of the substrate facing up. With reference to FIG. 5a, nest 502 includes a plurality of nest openings 504, which are formed through the thickness of nest 502. The size of each nest opening 504 is dimensioned to be slightly smaller than the dimension of the cut die to prevent the cut die from falling through. Each nest opening 504 is surrounded at its opening by retainer walls 506, which are disposed on top surface 508 of nest 502. Retainer walls 506 are arranged such that a cut die can rest on top surface 508 of nest 502 while overlying nest opening 504, yet have its edges retained within retainer wall 506 to limit the translational and rotational movement of the individual cut die. Exemplary retainer walls 506 may be more clearly seen in FIG. 5c. A plurality of locator pins 510 are shown, which may be employed to align the substrate prior to cutting to nest 502.

Nest 502 is configured to mate with a vacuum retainer plate 520. In the example of FIG. 5b, vacuum retainer plate 520 includes a vacuum block platform 520A and a base plate 520B. Vacuum block platform 520A includes a plurality of raised vacuum pedestals 522. Each vacuum pedestal 522 is configured to fit within a nest opening 504 of nest 502. Each vacuum pedestal 522 also includes a pedestal top surface 526 which is flat to form a vacuum seal with the under surface of the cut die during cutting. Each vacuum pedestal 522 further includes a vacuum port 528. When vacuum block platform 520A is mounted on baseplate 520B, the vacuum port is connected to a recessed chamber 530 in baseplate 520B. When a vacuum exists within recess chamber 530, as for example when vacuum lines are connected to port 532 in baseplate 520B, each vacuum port 528 of vacuum pedestal 522 provides vacuum to hold down the cut die during the cutting period.

When nest 502 having thereon a substrate to be cut is mounted on vacuum retainer plate by placing nest 502 on top of vacuum block platform 520A, the vacuum pedestals 522 protrude through nest openings 504 of nest 502. The height 540 of each vacuum pedestal 522 is dimensioned such that pedestal top surface 526 protrudes above top surface 508 of nest 502 when nest 502 is mated atop vacuum block platform 520A. Accordingly, the substrate is lifted off top surface 508 of nest 502 by pedestal top surface 526. Therefore, the height of retainer walls 506 are typically lower than the height at which the top surface of the vacuum pedestal protrudes above the top surface of the nest when the nest is mated on top of the vacuum block platform. For example, if the top surface of the vacuum pedestal protrudes above the top surface of the nest by 10 mil to lift the substrate off the top surface by 10 mil, the height of the retainer wall may be 5 mil. Thereafter, vacuum is turned on to allow vacuum port 528 to securely hold down the substrate by the bottom surfaces of the individual dies. After the vacuum is turned on, the substrate may be cut. Since the substrate is physically lifted off top surface 508 of nest 502, there is little risk of damage to the saw or top surface 508 of nest 502 during cutting. Furthermore, the height 540 of vacuum pedestal 522 may be adjusted to increase or decrease the distance from which the substrate is lifted off top surface 508 of nest 502 as desired. The height of the retainer walls 506 may also be adjusted as desired.

Adjacent vacuum pedestals 522 are separated by a recessed channel 550. This recessed channel may be made much wider than the width of the saw, thereby allowing some flexibility and tolerance in saw blade placement during cutting. In one example, the width of recessed channel 550 may range from between 6 mil to 12 mil permitting the saw blade to move from side to side as much as 5 mil without risking damage to the blade. Although it was not shown in FIG. 5a, the step portion and/or vacuum port may be disposed around the array nest openings to retain the scrap parts to facilitate their removal during subsequent washing or rinsing.

After cutting, the vacuum is left on and a top cover, which is not shown in the figures, is placed on top of nest 502 and the cut dies. The combination of the top cover, cut dies, and nest 502 forms a covered nest fixture. Since the vacuum is left on, each individual cut die is still held securely on pedestal top surface 526 of vacuum pedestal 522 at this point. The top cover preferably has a plurality of contact posts to contact designated locations on each cut die (e.g., the four corners of the cut die) to hold the cut die down by the weight of the top cover. Thereafter, the covered nest fixture is lifted off vacuum retainer plate 520. Since individual cut dies are no longer lifted off top surface 508 of nest 502, they drop down or are forced downward by the weight of the top cover to rest on top surface 508 and are constrained by retainer walls 506. In this manner, the top cover and top surface 508 trap each cut die in between while retainer walls 560 substantially limit the rotational and translational movement of the individual cut die. Thereafter, the covered nest fixture may be transported to a washing/rinsing/drying machine. Since each individual cut die is constrained by top surface 508 and retainer walls 506, the individual cut die are aligned for subsequent processing once the top cover is lifted off nest 502.

FIG. 6 illustrates, in accordance with one embodiment of the present invention, a flow chart of the automated die cutting technique using the nest and vacuum retainer plate arrangement of FIGS. 5a and 5 b. In step 600, the substrate is aligned to the retainer nest, BGA side up and molded side down. In one embodiment, the substrate is aligned to the nest by the locator pins on the nest (such as locator pin 510 on nest 502 of FIG. 5).

In step 602, the combination of the nest and substrate to be cut is positioned on top of the vacuum block platform to allow the top surface of the vacuum pedestal to lift the substrate off the top surface of the nest. In step 604, the vacuum is turned on to securely hold the substrate to the pedestal top surfaces of the vacuum block platform. In step 606, the substrate is cut with the BGA side up. One advantage of this implementation is that the die can be cut with a plastic or the molded side down, which is more forgiving towards the end of the cut.

In step 608 the top cover is placed on top of the cut dies and the nest while the vacuum is on. As mentioned earlier, the weight of the top cover holds the cut dies in place and forces the cut dies downward when the covered nest fixture is lifted from the vacuum block platform.

As mentioned earlier, when the covered nest fixture is lifted from the vacuum block platform, the individual cut dies fall down or are forced downward by the top cover toward the top surface of the nest to allow each individual cut die to be trapped between the plate and the top surface of the nest, with the sides of each cut die constrained by the retainer walls disposed around the nest opening. Thereafter, the dies may be further processed while being constrained between the top cover and the nest and by the retainer walls (e.g., washing, rinsing, drying and the like). Thereafter, the top cover may be lifted off to allow pick and place equipment to access the cut dies, which are now disposed on the top surface of the nest and constrained by the retainer walls, thereby aligned for the pick and place operation.

In accordance with another aspect of the present invention, vacuum pedestals 522 are formed of a resilient material that readily conforms to the undersurface of the cut die. Preferably, the resilient material of vacuum pedestals 522 is also at least slightly compressible to improve the seal that is formed between pedestal top surface 526 and the substrate when the substrate is disposed on pedestal top surface 526 and the vacuum is turned on. The resilient material of the vacuum pedestals, being softer, also has the advantage of being less likely to damage the saw blade should the saw blade inadvertently come into contact with the vacuum pedestals during dicing.

In one embodiment, a synthetic or natural rubber material that is capable of withstanding the rigors of repeated cutting and rinsing cycles is employed. By way of example, it is preferable that the vacuum pedestal material chosen be sufficient durable to minimize contamination to the cutting and rinsing process. Alternatively or additionally, it is preferable that the vacuum pedestal material chosen be able to withstand, for a commercially satisfactory number of cycles, the de-ionized water rinsing process that may be employed after cutting. Alternatively or additionally, it is preferable that the vacuum pedestal material possess anti-static properties to prevent damage to the integrated circuits being fabricated. Alternatively or additionally, it is preferable that the vacuum pedestal material possess a high friction coefficient relative to the undersurface of the substrate to prevent translational and/or rotational movement of the substrate and/or the individual dies during and after cutting. Alternatively or additionally, it is preferable that the vacuum pedestal material be machinable to simplify its manufacturing. In a preferred embodiment, a synthetic material known by the tradename “VITON” (available from McDowell & Company of Downey, Calif. or Pacific State Felt & Mfg. Co. Inc. of Hayward Calif.) is employed. The resilient VITON material, in addition to being conformable and/or compressible, also offers substantial advantages with respect to machinability, high friction, antistatic property, relative inertness to the rinsing chemicals, and general durability when employed in the vacuum pedestal application.

With reference to FIGS. 7A and 7B, a vacuum block platform 520A preferably includes a vacuum pedestal base 702 and a vacuum pedestal portion 704. Vacuum pedestal portion 704 includes a bridge portion 706, which is coupled to the individual vacuum pedestals 522 to provide mechanical support therefor. In one embodiment, both bridge portion 706 and the individual pedestals 522 of vacuum pedestal portion 704 are formed from the same block of resilient material. Machining is a preferred method for forming such a vacuum pedestal portion due to cost and ease of manufacturing considerations. However, any other suitable manufacturing techniques, such as molding, may also be employed to form vacuum pedestal portion 704.

Vacuum pedestal base 702 may be formed from any suitable material, including metal such as stainless steel. Vacuum base 702 includes a plurality of vacuum ports 730, which are configured to be in communication with the vacuum ports disposed within individual vacuum pedestals 522 of vacuum pedestal portion 704. Vacuum pedestal base 702 may be coupled to vacuum pedestal portion 704 using any suitable technique, including the use of adhesives or clamping. With reference to FIG. 7A, vacuum pedestal portion 704 includes groove 710 to permit a clamp to be inserted therein for the purpose of coupling vacuum pedestal base 702 to vacuum pedestal portion 704. In the example of FIG. 7B, screw holes 732 are provided in vacuum pedestal base 702 to allow the clamps to be attached thereto. FIG. 7B also shows additional screw holes 734, which facilitate the coupling of vacuum pedestal base 702 to an appropriate base plate, such as base plate 520B or a similarly suitable base plate. Alignment pin holes 736 are provided to accommodate alignment pins, which are employed to align a nest, such as nest 502, with the vacuum block platform during dicing.

FIG. 8 illustrates one exemplary clamp 802, including a base 804 and a tongue 806. When tongue 806 of clamp 802 is disposed within groove 710 of vacuum pedestal portion 704, base 804 may be coupled to the upper surface of vacuum pedestal base 702, for example, to fix vacuum pedestal portion 704 atop vacuum pedestal base 702. Note that base 804 of clamp 802 may be coupled to vacuum pedestal base 702 using any suitable technique, including for example, the use of adhesive or fasteners. In the example of FIG. 8, screw holes 810 are provided to accommodate screws, which are then screwed into screw holes 732 to fasten the clamp 802/vacuum pedestal portion 704 assembly with vacuum pedestal base 702. Clamping vacuum pedestal base 702 to vacuum pedestal portion 704 in this manner also advantageously permits vacuum pedestal portion 704 to be readily replaceable when worn.

FIG. 9 illustrates a top view of a vacuum pedestal 522 in accordance with one embodiment of the present invention. Each vacuum pedestal 522 preferably includes a countersunk portion 902, which is in communication with a vacuum port 904 disposed within vacuum pedestal 522. The cross-sectional area of countersunk portion 902 is preferably suitably dimensioned to allow the vacuum to develop a sufficient holding force to properly secure an individual die atop vacuum pedestal 522 during cutting while leaving enough of the top surface of vacuum pedestal 522 remaining to maintain proper sealing and frictional contact with the undersurface of the die.

In the embodiment of FIG. 7, the aforementioned resilient material is employed to form a substantial portion of the height of the individual vacuum pedestals above bridge portion 706. In another embodiment, the resilient material may take the form of a resilient capping arrangement that is disposed atop the vacuum pedestals. That is, at least a portion of the individual vacuum pedestal above bridge portion 706 may be formed of a material other than the resilient material (e.g., metal or hard plastic), either integrally with bridge portion 706 or separately but in a sealing relationship therewith. The resilient capping arrangement formed of the resilient material may take the form of a sheet of resilient material or individual pedestal caps having holes therein to accommodate the vacuum port of the vacuum pedestal. In one embodiment, the holes are dimensioned to provide the desired cross-sectional area (and therefore the desired vacuum hold-down force between the undersurface of the die and the top surface of the vacuum pedestal), thereby eliminating the need to machine the top surface of the vacuum pedestal to form the aforementioned countersunk portion. The resilient capping arrangement may be secured to the top surface of the vacuum pedestals of this embodiment using any suitable technique, including friction fit, clamping and/or the use of adhesives.

Although only a few embodiments of the present invention have been described, it should be understood that the present invention may be embodied in many other specific forms without departing from the spirit or the scope of the present invention. By way of example, It is possible omit the vacuum pedestal base and to attach the vacuum pedestal portion 704 directly to the base plate of the vacuum retainer plate if the vacuum retainer plate has the appropriate vacuum arrangement to provide vacuum to the vacuum ports within the vacuum pedestal portion. Such modification is within the skills of the artisan. As another example, while nest openings have been described as being completely open, i.e., nest openings allow substantially all balls in ball grid arrays to be exposed, nest openings may instead be only partially open. A partially open nest opening may be such that only some of the balls in a ball grid array are effectively directly exposed to a vacuum, while others are shielded from direct exposure to the vacuum. The use of partially open nest openings may be effective in allowing a substrate to be securely held by a vacuum during dicing. However, wash and dry processes used to remove residue from diced integrated circuit chips may become more complicated in that removal of residue from around the balls may be difficult when not all of the balls are exposed.

The nest openings in a nest have generally been described as being uniform. That is, all the nest openings in a single nest have been described as being of substantially the same shape. However, in one embodiment, the nest openings in a single nest may not all be of substantially the same shape. For example, some nest openings may be polygonal in shape, while other nest openings may be circular in shape. A nest with a nest openings which are of a variety of different shapes may be particularly suitable for use with a substrate which includes integrated circuit chips that have a variety of different ball grid array footprints.

It should be appreciated that although nest openings have been described as having polygonal, e.g., rectangular, and circular shapes, nest openings may generally have any shape that is suitable for accommodating ball grid arrays without departing from the spirit or the scope of the present invention. By way of example, in the event that a ball grid array has an irregular shape, the corresponding nest opening may also have substantially the same irregular shape. Such irregular shapes may include, but are not limited to, irregular polygonal shapes and assorted curved shapes.

As described above, nests are arranged to hold substrates which are substantially rectangular in shape. It should be appreciated, however, that nests may generally be reconfigured to accommodate substrates of virtually any size and shape. Nests may take on an overall circular shape when the substrates which are to be held using nests are circular in shape. Alternatively, nests may take on a general polygonal shape when the substrates which are to be held are effectively polygonal in shape.

While nests may include channels, or steps, which are intended to prevent scrap material generated during dicing processes from freely “flying” around, nests may not necessarily include channels. In one embodiment, nests may include clamping mechanism which hold scrap in place. Alternatively, in another embodiment, scrap material may not be constrained from moving after the dicing process if it is determined that substantially loose scrap material is not detrimental to the overall fabrication process.

Further, substrates which are retained in a nest may include any number of integrated circuit chips without departing from the spirit or the scope of the present invention. The number of chips depends both on the size of the chips and the size of the overall substrate. In one embodiment, a substrate which is approximately 8 inches by 2.5 inches may include 189 chips, each with a seven by seven ball grid array, in a twenty-seven by seven overall array. It should be appreciated, however, that the size of substrates and chips on the substrate may vary widely.

Nests have been described as being formed from aluminum or, more generally, metal. Typically, however, nests may be formed from any suitable material. For example, a nest may be formed from plastic. A plastic nest is likely to be lighter than a metal nest of the same size and shape and, as a result, may be preferable when the weight of the nest is an issue.

The steps associated with dicing a substrate that is held by a nest may generally be widely varied. Steps may be altered, added, or removed without departing from the spirit or the scope of the present invention. By way of example, a substrate may be loaded into a nest, which is then placed into a magazine of loaded nests that are placed one at a time onto a vacuum chuck. In other words, loaded nests may be queued prior to loading each nest onto a vacuum chuck. Also, in one embodiment, a covered nest fixture may be uncovered prior to removing the covered nest fixture from a wash and dry unit.

While the use of a nest has been described with respect to a substantially automatic dicing process, it should be appreciated that the nest may also be used in semi-automatic dicing processes. For instance, the nest may be used in a dicing process which requires manually loading the nest onto a vacuum chuck. The nest may also be used in a dicing process which requires that the nest is manually moved from a vacuum chuck to a wash and dry unit.

As described in some of the embodiments above, a substrate is placed in a nest such that the BGA side of the substrate faces into the nest. In other words, the “non-smooth” side of the substrate is effectively placed into the nest, and comes into substantially direct contact with a vacuum during a dicing process. In another embodiment, a substrate may be placed into a nest such that the “smooth,” e.g., non-BGA or die, side faces into the nest. In such cases, the substrate may be cut from the non-smooth side. The present examples are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope of the appended claims. 

What is claimed is:
 1. A method of separating a substrate into a plurality of integrated circuit chips, said substrate and said plurality of integrated circuit chips having a first side that is smoother than a second side, each of said plurality of integrated circuit chips including a ball grid array of contacts at said second side, said method comprising: providing a vacuum chuck having a plurality of vacuum pedestals and a channel structure that is disposed between adjacent vacuum pedestals, each of said vacuum pedestals corresponding to individual ones of said plurality of integrated circuit chips and each having an upper surface formed of a resilient material; disposing said first side of said substrate on said upper surface of said vacuum pedestals; holding said first side of said substrate securely against said upper surface of said vacuum pedestal with a vacuum, whereby said resilient material substantially seals the interface between said first side of said substrate and said upper surface of said vacuum pedestal when said substrate is being held by said vacuum; and dicing said substrate into the plurality of integrated circuit chips while said substrate is held against said upper surface of said vacuum pedestals.
 2. The method as recited in claim 1 wherein the vacuum chuck includes a base plate configured to distribute a vacuum and a vacuum block platform disposed on said base plate, the vacuum block platform including the vacuum pedestals, each of said vacuum pedestals rising above said base plate to support said first side of said substrate on said upper surface.
 3. The method as recited in claim 2 wherein each of the vacuum pedestals includes a vacuum port extending therethrough so as to allow the vacuum distributed by the base plate to hold said substrate against said upper surface of said vacuum pedestals.
 4. The method as recited in claim 1 wherein said channel structure is arranged to receive a saw blade during said dicing process, and wherein a width of said channel structure is substantially wider than the width of said saw blade to minimize blade fouling during said dicing process.
 5. The method as recited in claim 1 wherein said resilient material possesses a high friction coefficient relative to the first side of the said substrate and at least one of said plurality of chips to prevent translational and rotational movement of said substrate and at least on of said chips.
 6. The method as recited in claim 1 wherein said substrate is a circuit board.
 7. The method as recited in claim 1 wherein said substrate is rectangularly shaped.
 8. The method as recited in claim 1 further comprising aligning said substrate on said vacuum chuck.
 9. The method as recited in claim 8 wherein said substrate includes locator hole for aligning said substrate.
 10. The method as recited in claim 1 further comprising providing a grid arranged nest configured to support said substrate and plurality of chips during transportation of the chips, said grid arranged nest being arranged to cooperate with said vacuum chuck in a mating relationship; placing said substrate on said grid arranged nest; and mating said grid arranged nest with said vacuum chuck so that said substrate is disposed on said vacuum chuck.
 11. The method as recited in claim 10 wherein said grid arranged nest has a first and a second side, said grid arranged nest including a grid which defines at least one nest opening, said nest opening having an opening area that is smaller than an area of an individual one of said plurality of integrated circuit chips.
 12. The method as recited in claim 11 wherein said vacuum pedestal is configured to be disposed through said nest opening from said second nest side and to protrude above said first nest side when said vacuum pedestal is mated with said grid arranged nest.
 13. The method as recited in claim 10 further comprising: providing a cover configured for supporting said plurality of chips, said cover being arranged to cooperate with said grid arranged nest; and placing said cover over said nest so as to form a covered nest fixture that effectively constrains said chips between said cover and said grid arranged nest.
 14. The method as recited in claim 1 further comprising: releasing said integrated circuit chips from said vacuum; and transporting said integrated circuit chips from said vacuum chuck to another processing station.
 15. The method as recited in claim 14 wherein said processing station is a wash and dry unit. 